Journal of African Earth Sciences 100 (2014) 96–108 Contents lists available at ScienceDirect Journal of African Earth Sciences journal homepage: www.elsevier.com/locate/jafrearsci Formation of the Cameroon Volcanic Line by lithospheric basal erosion: Insight from mantle seismic anisotropy ⇑ A.A. Elsheikh , S.S. Gao, K.H. Liu Department of Geosciences and Geological and Petroleum Engineering, Missouri University of Science and Technology, Rolla, MO 65409, USA article info abstract Article history: The formation mechanism of intraplate volcanism such as that along the Cameroon Volcanic Line (CVL) is Received 26 December 2013 one of the controversial problems in global tectonics. Models proposed by previous studies include re- Received in revised form 13 June 2014 activation of ancient suture zones, lithospheric thinning by mantle plumes, and edge-driven mantle con- Accepted 15 June 2014 vection. To provide additional constraints on the models for the formation of the CVL, we measured Available online 27 June 2014 shear-wave splitting parameters at 36 stations in the vicinity of the CVL using a robust procedure involv- ing automatic batch processing and manual screening to reliably assess and objectively rank shear-wave Keywords: splitting parameters (fast polarization directions and splitting times). The resulting 432 pairs of splitting Shear-wave splitting parameters show a systematic spatial variation. Most of the measurements with ray-piercing points (at Cameroon Volcanic Line Intraplate volcanic segments 200 km depth) beneath the CVL show a fast direction that is parallel to the volcanic line, while the fast Lithospheric channel directions along the coastline are parallel to the continental margin. The observations can best be inter- preted using a model that involves a channel flow at the bottom of the lithosphere originated from the NE-ward movement of the asthenosphere relative to the African plate. We hypothesize that progressive thinning of the lithosphere through basal erosion by the flow leads to decompression melting and is responsible for the formation of the CVL. The model is consistent with the lack of age progression of the volcanoes in the CVL, can explain the formation of both the continental and oceanic sections of the CVL, and is supported by previous geophysical observations and geodynamic modeling results. Ó 2014 Elsevier Ltd. All rights reserved. 1. Introduction with the Atlantic coastline at the joint point between the E–W and N–S segments of the coastline (Fig. 2). Most of the Earth’s magmatism is associated with dehydration Many studies proposed that the CVL was the result of the NE- of minerals in subducting slabs and with decompression melting ward movement of the African plate over a mantle plume that is along mid-ocean ridges, and thus can be well-explained by the the- currently beneath St. Helena (e.g., Morgan, 1983)(Fig. 1). This ory of plate tectonics (e.g., Turcotte and Oxburgh, 1978; Courtillot model predicts that the age of the volcanoes decreases toward et al., 2003). The formation mechanism for intraplate magmatism, the SW. Such an age progression, however, is not observed (e.g., on the other hand, remains enigmatic. Various models have been Fitton and Dunlop, 1985). Additionally, 3He/4He ratios measured proposed to explain intraplate magmatism, including those involv- along the CVL are lower than those observed at typical hotspots ing mantle plumes (Morgan, 1972; Courtillot et al., 2003), tensional such as Loihi and Iceland (Aka et al., 2004), probably suggesting cracking in the lithosphere (Turcotte and Oxburgh, 1978; an upper-mantle origin of the magmatism. Other studies con- Anderson, 2000), and edge-driven convection (EDC) (King and cluded that the CVL was due to decompression melting beneath Anderson, 1998). re-activated shear zones on the African continent (e.g., Fairhead, The African plate is ideal for studying intraplate magmatism. It 1988). This model, while can explain the lack of age progression, contains several intraplate volcanic segments or centers that are cannot satisfactorily explain the existence of the oceanic section remote from the African plate boundaries (Fig. 1). One of such seg- of the CVL. The third group of studies advocated edge-driven con- ments is the NE–SW oriented Cameroon Volcanic Line (CVL), which vection as the major cause of the CVL (King and Ritsema, 2000; consists of a continental and an oceanic section. The CVL intercepts Koch et al., 2012; Milelli et al., 2012). This model suggests that the upwelling flow thins the lithosphere and creates a line of vol- canoes parallel to the boundary between two areas with contrast- ⇑ Corresponding author. Tel.: +1 5733414058; fax: +1 5733416935. ing lithospheric thickness. In the study area, the northern edge of E-mail addresses: [email protected] (A.A. Elsheikh), [email protected] (S.S. Gao), [email protected] (K.H. Liu). the Congo craton is a potential locale for the EDC to occur and thus http://dx.doi.org/10.1016/j.jafrearsci.2014.06.011 1464-343X/Ó 2014 Elsevier Ltd. All rights reserved. A.A. Elsheikh et al. / Journal of African Earth Sciences 100 (2014) 96–108 97 Fig. 1. Topographic relief map of Africa showing major intraplate volcanic centers and cratons (Turcotte and Oxburgh, 1978; Abdelsalam et al., 2011). CVL, Cameroon Volcanic Line. TC, Tanzania Craton. The area inside the red dashed rectangle is shown in Figs. 2 and 3. The green arrows represent absolute plate motion (APM) vectors calculated using the GMHRF model (Doubrovine et al., 2012), and the black arrows show APM vectors determined by the HS3-NUVEL1A model (Gripp and Gordon, 2002). The blue arrows indicate the horizontal component of mantle flow predicted at 250 km depth (Forte et al., 2010). Red stars represent the locations of the Atlantic mantle plumes (Doubrovine et al., 2012). (For interpretation of the references to color in this figure legend, the reader is referred to the web version of this article.) could be responsible for the formation of the continental section of and Rondenay, 2006; Conrad et al., 2007). Numerical modeling and the CVL (Fig. 3). However, this model cannot explain the orienta- experimental mineral physics studies indicate that under uniaxial tion of the oceanic section of the CVL, because the anticipated compression, the olivine a-axis rotates to be orthogonal to the strike of the zone of thinned oceanic lithosphere should be parallel maximum compressional strain direction. Under pure shear, it to the coastline, while the actual CVL has a NE–SW strike. In addi- becomes perpendicular to the shortening direction; and under pro- tion, as described below, neither the plume nor the EDC model is gressive simple shear, it aligns parallel to the flow direction (Ribe supported by shear-wave splitting (SWS) measurements. and Yu, 1991; Chastel et al., 1993; Zhang and Karato, 1995; Splitting analysis of P-to-S converted phases at the core-mantle Savage, 1999; Liu, 2009). Therefore, the fast direction may reveal boundary on the receiver side, including the PKS, SKKS, and SKS the flow direction in the asthenosphere as observed in ocean (hereinafter collectively referred to as XKS) phases, is considered basins, continental rifts, and passive margins (Wolfe and to be one of the most effective tools in measuring seismic anisot- Solomon, 1998; Gao et al., 1994, 1997, 2008, 2010; Refayee et al., ropy, which is mostly caused by deformational processes in the 2013). mantle (see Silver, 1996; Savage, 1999, and Fouch and Rondenay, In the lithosphere, U is primarily parallel to the trend of past 2006 for reviews). Numerous XKS splitting studies demonstrated tectonic events, as revealed at numerous locales (McNamara that the spatial distribution of the two splitting parameters U, et al., 1994; Liu et al., 1995; Silver, 1996; Barruol and Hoffmann, which is the polarization direction of the faster wave, and dt, the 1999; Fouch and Rondenay, 2006; Li and Chen, 2006; Liu, 2009). splitting time between the faster and slower waves, are crucial to In addition, vertical magmatic dikes in the lithosphere can result understand mantle circulation patterns. The fast direction reflects in XKS splitting with a fast direction parallel to the main strike the mantle deformation direction, while the splitting time quanti- direction of the dikes (Gao et al., 1997, 2010). This mechanism fies the magnitude of the mantle deformation (Conrad and Behn, was suggested to explain rift-parallel fast directions detected in 2010; Kreemer, 2009). active continental rifts such as the Baikal rift zone (Gao et al., The coefficient of anisotropy is defined as (Vfast À Vslow)/Vmean 1997), the East African rift system (Gao et al., 1997, 2010; where Vfast and Vslow are the fast and slow shear-wave velocities, Kendall et al., 2005), and failed rifts such as the southern Oklahoma respectively and Vmean is the mean velocity (Birch, 1960; Wolfe aulacogen (Gao et al., 2008). and Solomon, 1998). The global average of the splitting time observed using teleseismic XKS waves is 1.0 s, which corresponds 2. Geophysical background to a thickness of about 100 km for a 4% anisotropy (Silver, 1996). Olivine lattice-preferred orientations (LPO) likely forms as a result The CVL is an 1600 km elongated Y-shaped feature of of dislocation creep deformation, leading to a macroscopic anisot- Cenozoic volcanoes (e.g., Fitton, 1987; Aka et al., 2004; Tokam ropy in the upper mantle (e.g., McKenzie, 1979; Ribe, 1989; Fouch et al., 2010; Reusch et al., 2010; Milelli et al., 2012)(Fig. 3). It is 98 A.A. Elsheikh et al. / Journal of African Earth Sciences 100 (2014) 96–108 Fig. 2. Major tectonic elements of western and central Africa showing main geological subdivision units (International Geological Map of Africa, 1990). The white squares and rectangles show seismic stations used in the study. located between the Congo craton to the south and the Ouban- van Heijst, 2000; Priestley et al., 2008; Reusch et al., 2010).
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